Catalytic converter apparatus

ABSTRACT

A catalytic converter apparatus includes a housing having an inlet port, an outlet port, a chamber, an access opening, and an interior sealing surface generally encompassing a periphery of one of the inlet and outlet ports in the chamber. A substrate assembly is insertable into the chamber and removable from the chamber through the access opening, and includes a catalyst matrix for treating fluid. A positioning mechanism removably supports the substrate assembly within the chamber so that movement of the substrate assembly in a lateral direction generally parallel to the interior sealing surface moves the substrate assembly in an axial direction generally perpendicular to the interior sealing surface. The positioning mechanism may guide the substrate assembly in the axial direction into sealing engagement with the one of the inlet and outlet ports to provide a fluid flow path through the catalyst matrix between the inlet and outlet ports.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. application Ser. No.13/457,981 filed on Apr. 27, 2012, the entire contents of which arehereby incorporated herein by reference.

FIELD

The present disclosure relates generally to catalytic converterapparatuses, and particularly to installing a catalyst matrix within ahousing.

BACKGROUND

The following paragraphs are not an admission that anything discussed inthem is prior art or part of the knowledge of persons skilled in theart.

U.S. Pat. No. 7,410,621 describes a catalyst substrate with a peripheralmantle extending thereabout and having opposite end walls between whichthe substrate is disposed. At least one of the end walls acts as aforward seal which is maintained in close proximity with a correspondingsealing surface toward an inlet end of the catalytic converter housing.A retaining member is provided which maintains the sealing surfaces inclose proximity to define a labyrinth seal therebetween.

U.S. Pat. No. 7,655,194 describes a catalyst substrate support for acorrugated foil honeycomb matrix defining a plurality of passagesextending therethrough which are generally parallel to an axis. Aperipheral mantle extends about an outer perimeter of the matrix and hasinwardly extending flanges which extend across an outer periphery of theopposite end faces to cover outermost of the passages and restrict fluidflow between the peripheral mantle and the matrix. The outer perimeterof the matrix and the peripheral mantle may be spaced apart to define agap for accommodating differential thermal expansions of the matrix andthe peripheral mantle, the gap being smaller than a height of theinwardly extending flanges. Cross members secured to each of theopposite end faces of the matrix may transfer at least part of thegravitational load of the matrix to the mantle.

U.S. Pat. No. 7,919,052 describes securing a catalyst element in acatalytic converter with a bolted bar. The catalytic converter has ahousing. The housing defines a conduit and has a support wall definingan opening in the conduit. A removable catalyst element covers theopening for treating an exhaust gas passing through the conduit. Aremovable bar abuts the catalyst element. A first end of the bar isanchored to the wall and a second end of the bar is bolted to the wallthus clamping the catalyst element between the wall and the bar.

SUMMARY

The following paragraphs are intended to introduce the reader to themore detailed description that follows and not to define or limit theclaimed subject matter.

According to an aspect of the present disclosure, a catalytic converterapparatus may include: a housing including an inlet port, an outlet portspaced apart from the inlet port, a chamber between the inlet and outletports, an access opening for access to the chamber, and an interiorsealing surface generally encompassing a periphery of one of the inletand outlet ports in the chamber; a substrate assembly insertable intothe chamber and removable from the chamber through the access opening,the substrate assembly including a catalyst matrix for treating fluid;and a positioning mechanism for removably supporting the substrateassembly within the chamber so that movement of the substrate assemblyin a lateral direction generally parallel to the interior sealingsurface moves the substrate assembly in an axial direction generallyperpendicular to the interior sealing surface.

According to an aspect of the present disclosure, a method of installinga substrate assembly in a housing, the housing including an inlet port,an outlet port spaced apart from the inlet port, a chamber between theinlet and outlet ports, an access opening, and an interior sealingsurface generally encompassing a periphery of one of the inlet andoutlet ports in the chamber, may include: inserting the substrateassembly into the chamber through the access opening; engaging thesubstrate assembly with a positioning mechanism in the chamber, thepositioning mechanism removably supporting the substrate assembly withinthe chamber so that movement of the substrate assembly in a lateraldirection generally parallel to the interior sealing surface moves thesubstrate assembly in an axial direction generally perpendicular to theinterior sealing surface; and moving the substrate assembly in thelateral direction relative to the housing to guide the substrateassembly in the axial direction into sealing engagement with the one ofthe inlet and outlet ports, thereby providing a fluid flow path throughthe substrate assembly between the inlet and outlet ports.

According to an aspect of the present disclosure, a catalytic converterapparatus may include: a housing including a port, and an interiorsealing surface generally encompassing a periphery of the port; and asubstrate assembly removably supported relative to the housing, thesubstrate assembly including a frame, a catalyst matrix supported by theframe and including an end face, and a flange element extending about aperiphery of the end face of the catalyst matrix, wherein the flangeelement abuts the interior sealing surface, wherein the frame engagesthe flange element, and wherein the frame distributes force to theflange element so that the flange element bears against the interiorsealing surface to provide a generally sealed fluid flow path throughthe catalyst matrix and the port.

BRIEF DESCRIPTION OF THE DRAWINGS

The drawings included herewith are for illustrating various examples ofapparatuses and methods of the present disclosure and are not intendedto limit the scope of what is taught in any way. In the drawings:

FIG. 1 is a front perspective view of a catalyst matrix and a collarmounted to the catalyst matrix;

FIG. 2 is a rear perspective view of the catalyst matrix and the collarof FIG. 1;

FIGS. 3 and 4 are front and side views of the catalyst matrix and thecollar of FIG. 1;

FIG. 5 is an enlarged sectional view along line 5-5 in FIG. 4;

FIG. 6 is a front perspective view of the catalyst matrix and the collarof FIG. 1 mounted to a frame, forming a substrate assembly;

FIGS. 7 and 8 are front and side views of the frame of FIG. 6;

FIG. 9 is a front perspective view of a housing;

FIG. 10 is a partially exploded view of the housing of FIG. 9, with acover of the housing spaced away from a base portion;

FIG. 11 is a top view of the housing of FIG. 9, shown without the cover;

FIG. 12 is a sectional view along line 12-12 in FIG. 11;

FIGS. 13 and 14 are sectional views along line 13-13 in FIG. 11, andshowing the substrate assembly being installed in the housing;

FIGS. 15 and 16 are enlarged sectional views of FIG. 14;

FIG. 17 is a perspective view of a retaining device; and

FIG. 18 is a further sectional view along line 13-13 in FIG. 11, andshowing a pair of the substrate assemblies installed in the housing.

DETAILED DESCRIPTION

Various apparatuses or methods will be described below to provide anexample of an embodiment of each claimed invention. No embodimentdescribed below limits any claimed invention and any claimed inventionmay cover apparatuses and methods that differ from those describedbelow. The claimed inventions are not limited to apparatuses and methodshaving all of the features of any one apparatus or method describedbelow or to features common to multiple or all of the apparatuses ormethods described below. It is possible that an apparatus or methoddescribed below is not an embodiment of any claimed invention. Anyinvention disclosed in an apparatus or method described below that isnot claimed in this document may be the subject matter of anotherprotective instrument, for example, a continuing patent application, andthe applicant(s), inventor(s) and/or owner(s) do not intend to abandon,disclaim or dedicate to the public any such invention by its disclosurein this document.

Catalytic converters may be broadly grouped into vehicle sized units andstationary engine or industrial sized units. Vehicle sized units may beconsiderably smaller than industrial sized ones, and accordingly may berelatively easy to remove and to disassemble. For example, the diameterof a catalyst substrate for vehicle sized units may measure less than afoot (approximately 0.3 m). In contrast, large industrial sized unitsmay have catalyst substrate diameters that measure up to, for examplebut not limited to, about six feet (approximately 2 m). The associatedducting and sheer size of the components may inhibit simple removal andaxial disassembly of an industrial sized unit from a gas flow line inwhich it is mounted for replacing the catalyst substrate. Instead, largeindustrial sized catalytic converter housings may be provided with alateral access port for removal of the catalyst substrate from a side ofthe housing, without removal or axial separation of the housing from itsassociated ductwork.

In general, the concepts described herein pertain to catalytic converterapparatuses that may be suitable for relatively large, industrial orstationary power applications. The apparatuses include a housing, asubstrate assembly that is inserted into and removed from the housingthrough an access opening, and a positioning mechanism that removablysupports the substrate assembly in the housing and enables sealingengagement between the substrate assembly and a port of the housing.

Referring to FIGS. 1 and 2, an example of a catalyst matrix is showngenerally at reference number 20. The catalyst matrix 20 includesgenerally opposite first and second end faces 22, 24. In the exampleillustrated, the catalyst matrix 20 is generally circular in crosssection, and generally cylindrical in shape having a cylindricalperiphery or side surface 32 (FIG. 5) extending between the end faces22, 24. In some examples, the catalyst matrix may be configured to haveother shapes and sizes.

The catalyst matrix 20 is adapted to treat or otherwise condition fluidsthat may include, for example but not limited to, exhaust gases from aninternal combustion engine, or process fluid from an industrial process.The catalyst matrix 20 includes a substrate that may be formed of, forexample but not limited to, a ceramic honeycomb, corrugated metal foilsheets, flat metal foil sheets, and/or another material structured toprovide a relatively high surface area for contact with the fluid to betreated, and may be loaded with an effective amount of catalyticmaterial. In the example illustrated (FIG. 5), the catalyst matrix 20defines passages 26 that extend generally between the end faces 22, 24to permit fluid flow therethrough. The passages 26 may be generallyparallel to a substrate axis 28 of the catalyst matrix 20 (shown inFIGS. 3 and 4).

With reference again to FIG. 5, the catalyst matrix 20 is shown toinclude a peripheral mantle 30 that extends about the side surface 32.The peripheral mantle 30 may be generally fluid impervious, so thatfluid flow is constrained in the catalyst matrix 20 between the endfaces 22, 24. In the example illustrated, the peripheral mantle 30 hasopposed end edges 30 a, 30 b that are spaced axially outboard of the endfaces 22, 24 to define gaps 34, 36, respectively. The gaps 34, 36 mayhelp to accommodate dimensional variations during manufacturing.Furthermore, the gaps 34, 36 may accommodate different rates ofexpansion and contraction of the peripheral mantle 30 relative to therest of the catalyst matrix 20.

Referring again to FIGS. 1 and 2, a collar 38 is mounted around thecatalyst matrix 20. The collar 38 includes a flange element 40 thatextends generally about a periphery of the first end face 22. The flangeelement 40 may be formed of a flexible, resilient, and heat resistantmaterial, for example but not limited to, stainless steel. In theexample illustrated, the flange element 40 is coupled to an annular wall42 that generally wraps around at least a portion of the length of theperipheral mantle 30. The collar 38 may be formed of a generallyrectangular sheet of metal, bent and curved into shape to define theflange element 40 and the annular wall 42, with ends joined at a seam44. In some examples, the collar may be formed by punching or pressingoperations.

In the example illustrated, the flange element 40 is flared outwardly atan angle relative to the annular wall 42. As described in further detailbelow, the flange element 40 is configured to flex relative to theannular wall 42 (shown in FIG. 16). Furthermore, a line or region ofreduced thickness 46 (also shown in FIG. 16) may be arranged generallybetween the flange element 40 and the annular wall 42. The line ofreduced thickness 46 may permit failure of the collar 38 in misfire orother abnormally high pressure pulsation situations, so as to avoid orat least reduce damage to the catalyst matrix 20.

Referring again to FIG. 5, in some examples, the annular wall 42 of thecollar 38 may be fixed to the peripheral mantle 30 by a weld 48. In someexamples, the annular wall 42 and the peripheral mantle 30 may beconfigured for friction fit or interference fit engagement, so that thecollar 38 is generally securely fixed to the peripheral mantle 30 of thecatalyst matrix 20.

In some examples, the peripheral mantle 30 may be omitted, as long asthe side surface 32 of the catalyst matrix 20 is sufficiently fluidimpervious. In these examples, the annular wall 42 may be fixed to theside surface 32. Furthermore, in some examples, the annular wall 42 maybe omitted, and the flange element 40 may be fixed to the peripheralmantle 30, or to the side surface 32. In some examples, the flangeelement 40 may be made integral with the peripheral mantle 30. In someexamples, the flange element 40 may be formed integral with the catalystmatrix 20. Various configurations are possible.

Referring now to FIG. 6, a substrate assembly 50 is formed by acombination of the catalyst matrix 20 and the collar 38, held in a frame52. Referring to FIGS. 6, 7 and 8, the frame 52 is shown to include atop side plate 54, a bottom side plate 56 spaced apart from the top sideplate 54, a left side plate 58, a right side plate 60 spaced apart fromthe left side plate 58, and a front plate 62 extending generally betweenthe side plates 54, 56 and the side plates 58, 60. The top side plate 54may include cutouts 64, and the side plates 58, 60 may include cutouts66, 68, respectively, which may help to reduce weight of the frame 52and allow for circulation of fluid around the catalyst matrix 20.

In the example illustrated, the front plate 62 of the frame 52 includesa circular opening 70 that is sized and shaped to slidingly receive thecatalyst matrix 20, but not the flange element 40, so that the flangeelement 40 engages the front plate 62 in opposed relation. Furthermore,the bottom side plate 56 extends upwardly at its rear edge to form anupstanding support plate 72, which may help to bear at least a portionof the weight of the catalyst matrix 20 once received in the circularopening 70. Moreover, the top side plate 54 extends to provide arearward lip 74, which may serve as a handle for a user to hold thesubstrate assembly 50. Finally, the frame 52 includes outwardlyextending first and second flaps 76, 78 coupled to the side plates 58,60, respectively. The flaps 76, 78 are arranged at a flap angle 112relative to the front plate 62.

The plates 54, 56, 58, 60, 62 may all be formed from a single sheet ofmaterial (for example, stainless steel). In the example illustrated,each of the side plates 54, 56, 58, 60 is formed (for example, using abending brake) at about a 90° angle relative to the front plate 62, andeach may be connected to its respective adjacent two of the side plates54, 56, 58, 60, thereby forming a relatively rigid yet lightweightstructure. In particular, the side plates 54, 56, 58, 60, being arrangedorthogonally relative to the front plate 62, may provide stiffness togenerally evenly distribute force between the flaps 76, 78 and the frontplate 62.

Referring to FIGS. 9 and 10, an example of a housing is shown generallyat reference numeral 80. The housing 80 is shown to be generallybox-shaped, and includes a first end wall 82, a second end wall 84, afirst side wall 86, a second side wall 88, and a bottom wall 89. Thefirst end wall 82 includes an inlet port 90, and the second end wall 84includes an outlet port 92. In use, the ports 90, 92 are connected to anupstream source of fluid to be treated and downstream equipment,respectively, or vice versa. The ports 90, 92 may be bolted, welded, orotherwise connected to piping (not shown) to supply the fluid to betreated to the housing 80, and deliver the treated fluid away from thehousing 80.

In the example illustrated, the ports 90, 92 are shown to be generallycircular openings, and are arranged in alignment to define a centralaxis 94 that extends through the housing 80. Thus, in the exampleillustrated, the housing 80 defines a fluid conduit oriented generallyparallel to the central axis 94 between the ports 90, 92. The end walls82, 84 may be generally transversely oriented relative to the centralaxis 94. Shaping of the ports 90, 92 may generally match the end faces22, 24 of the catalyst matrix 20. However, in some examples, the portsmay be configured to have other shapes, which may differ from oneanother, and the ports may not be arranged in alignment.

The housing 80 includes a removable cover 96 that, once removed, exposesan access opening 98 in a base portion 99 of the housing 80 (shown inFIG. 10). The cover 96 is shown as a generally planar panel, having atop handle 100. The cover 96 is attached in a sealed, removable mannerto a sill 102. An optional gasket 104 may be sandwiched between thecover 96 and the sill 102 to form a seal therebetween. In the exampleillustrated, the cover 96 and the sill 102 each include holes that arealigned when the cover 96 is properly mated with the sill 102, and aplurality of bolts 106 are used to connect the cover 96 and the sill 102via the holes. The bolts 106 engage nuts 107, which are fixed relativeto the sill 102 (shown in FIG. 13). The bolts 106 may provide a solidconnection, and facilitate relatively easy removal of the cover 96 toexpose the access opening 98. In some examples, other means of sealablyattaching a door or a cover to enclose the access opening 98 may beimplemented.

Although the port 90 is described herein as an inlet, and the port 92 isdescribed as an outlet, the ports 90, 92 may instead be connected to thedownstream equipment and the upstream source of fluid, respectively, sothat the port 92 receives an incoming stream of fluid. Accordingly, inthe example illustrated, each side is illustrated generally as a mirrorimage of the other, and, for simplicity and clarity of illustration,only the side adjacent to the inlet port 90 is described in detail.

Referring now to FIGS. 11 and 12, a chamber 108 is defined between theports 90, 92. In the chamber 108, an interior sealing surface 110generally encompasses a periphery of the port 90. A positioningmechanism 114 is arranged in the chamber 108. The positioning mechanism114 is configured to removably support the substrate assembly 50 (shownin FIG. 6) within the chamber 108.

In the example illustrated, the positioning mechanism 114 includes firstand second bracket members 116, 118 fixed to the side walls 86, 88,respectively. The bracket members 116, 118 include elongate first tabs120, 122, respectively, which are spaced apart from one another andextend upwardly within the chamber 108. The first tabs 120, 122 presentfirst and second guiding surfaces 124, 126, which are inclined at a tabangle 128 relative to the interior sealing surface 110. The guidingsurfaces 124, 126 are configured to slidingly receiving the frame 52 ofthe substrate assembly 50 (shown in FIG. 6).

The bracket members 116, 118 may also include second tabs 130, 132 andthird tabs 134, 136, respectively, each of which may be orientedgenerally parallel to the interior sealing surface 110, and are disposedcloser to the interior sealing surface 110 than the first tabs 120, 122.The tabs 130, 132 and the tabs 134, 136 may help to guide the sideplates 58, 60 to locate the frame 52 of the substrate assembly 50 (shownin FIG. 6) generally intermediate between the side walls 86, 88. Atransverse dimension 138 between inward ends of the tabs 130, 134 andthe tabs 132, 136 may accommodate a transverse width of the frame 52between the side plates 58, 60. The tabs 130, 134 (FIG. 10) may alsoinclude holes 141 for anchoring a retaining device, described below.Although not shown, similar holes may also be provided on the tabs 132,136, on the other side of the chamber 108.

Referring to FIGS. 13 and 14, the substrate assembly 50, including thecatalyst matrix 20, the collar 38 and the frame 52, may be inserted intothe chamber 108 and removed from the chamber 108 through the accessopening 98. The first flap 76 of the frame 52 slidingly mates with thefirst guiding surface 124. Similarly, although not shown, the secondflap 78 of the frame 52 slidingly mates with the second guiding surface126. The guiding surfaces 124, 126 guide the frame 52 towards the inletport 90, so that movement of the substrate assembly 50 in a lateraldirection 142 correspondingly moves the substrate assembly in an axialdirection 144. The frame 52 may be moved until the flange element 40abuts and bears against the interior sealing surface 110, and thesubstrate axis 28 of the catalyst matrix 20 (see FIGS. 3 and 4) isgenerally collinear with the axis of the 94 of the housing 80 (see FIGS.9 and 10).

In the example illustrated, the directions 142, 144 are generallyorthogonal. The lateral direction 142 is shown to be downwards, and isgenerally parallel to the interior sealing surface 110. The axialdirection 144 is shown to be outwards, and is generally perpendicular tothe interior sealing surface 110.

Referring now to FIG. 15, the first flap 76 of the frame 52 engages thefirst guiding surface 124 so that force applied to the frame 52 in thelateral direction 142 resolves into force in the axial direction 144. Inthis manner, the substrate assembly 50 is positioned against theinterior sealing surface 110 by means of mechanical wedge action.Furthermore, the flap angle 112 of the flaps 76, 78 (see FIG. 8) maygenerally match the tab angle 128 of the guiding surfaces 124, 126, sothat the flaps 76, 78 and the guiding surfaces 124, 126 may frictionallyengage generally along their length. In some examples, friction acrossthe surface area between the flaps 76, 78 and the guiding surfaces 124,126 may help to lock the flaps 76, 78 into position relative to theguiding surfaces 124, 126.

Referring to FIG. 16, the flange element 40 flexes against the interiorsealing surface 110, which may help to form a seal without a gasket. Thefront plate 62 is shown to be arranged parallel to the interior sealingsurface 110. In the example illustrated, the front plate 62 engages aninward surface 152 of the flange element 40 to cause the flange element40 to flex against the interior sealing surface 110. Accordingly, thefront plate 62 may distribute sealing force to the flange element 40generally without transmitting a portion of the load through thecatalyst matrix 20.

The amount of force in which the flange element 40 bears against theinterior sealing surface 110 may vary, and should be sufficient tomaintain the seal under expected operating pressure conditions withfluid flowing through the passages 26. As mentioned above, in the eventof misfire or abnormally high pressure pulsations, the line of reducedthickness 46 may permit failure of the collar 38 generally between theflange element 40 and the annular wall 42, in order to avoid or at leastreduce damage to the catalyst matrix 20.

The interior sealing surface 110 may be a generally planar surface sothat good contact may be made with an outward edge 151 of the flangeelement 40. In the example illustrated, the interior sealing surface 110is formed by first and second inner wall elements 146, 148 that arefixed to the end wall 82, generally surrounding the inlet port 90 (seealso FIG. 13). The inner wall elements 146, 148 are shown to begenerally ring-shaped, and may be formed of a heat-resistant materialsuch as stainless steel, or a ceramic material. The laminated structureof the inner wall elements 146, 148 may be relatively rigid and exhibitlittle deformation when bearing the force applied by the flange element40. The inner wall elements 146, 148 may also serve as a thermal barrierto reduce conduction of heat out of the chamber 108.

With reference to both FIGS. 5 and 16, the outward edge 151 of theflange element 40 is axially outboard of the end edge 30 a, providing anoffset 150 when the flange element 40 is unloaded (FIG. 5), and anoffset 154 when the flange element 40 is in a flexed condition againstthe interior sealing surface 110 (FIG. 16). With the offset 154, in theevent that there is not perfect alignment between the substrate assembly50 and the interior sealing surface 110, or slight dimensionalvariations between these parts, the peripheral mantle 30 may notinterfere with the flange element 40 in forming a seal with the interiorsealing surface 110.

Referring to FIG. 17, an optional retaining device 156 may be used tohelp maintain the substrate assembly 50 in sealing engagement within thehousing 80. In the example illustrated, the retaining device 156includes an elongate bar 158, with fastening pins 160 arranged on eitherend. The pins 160 are received in the holes 141 (shown in FIG. 10) tolock the retaining device 156 in place towards the top of the bracketmembers 116, 118 (shown in FIG. 11). One or more engagement elements 162extend from below a bottom edge of the bar 158, with cutaways 164arranged generally therebetween. In the example illustrated, theengagement elements 162 are flexible and resilient, and are arranged toexert a force onto the frame 52 generally in the lateral direction 142(see FIG. 13). In some examples, the cover 96 or another componentwithin the chamber 108 may be arranged to exert force onto the frame 52and/or the substrate assembly 50 to maintain sealed engagement betweenthe substrate assembly 50 and the housing 80.

Referring to FIG. 18, a catalyst converter apparatus 166 includes two ofthe substrate assemblies 50 received in the housing 80, with the cover96 fixed in place. In the example illustrated, the catalytic converterapparatus 166 removably houses two of the substrate assemblies 50.However, it will be recognized that the apparatus may be configured toremovably contain only one of the substrate assemblies 50, or three ormore of the substrate assemblies 50, arranged in series.

In use, the catalytic converter apparatus 166 is connected to piping(not shown) so that the fluid to be treated is supplied to the inletport 90, and treated fluid is delivered away from the outlet port 92.For example, in engine exhaust treatment implementations, the inlet port90 may be bolted, welded, or otherwise connected (e.g., using one ormore band clamps) to piping that is attached to an engine exhaustmanifold. The outlet port 92 may similarly be bolted, welded, orotherwise connected to piping that leads optionally to a heat exchangerand/or a muffler device, and delivers the treated exhaust gas to theatmosphere.

The cover 96 is unfastened, and both of the substrate assemblies 50 areinserted into the housing 80, and are removably supported therein. Theflange element 40 of each of the substrate assemblies 50 bears outwardlyagainst interior sealing surfaces 110, 168 in sealing engagement, whichprovides a fluid flow path 170 through the catalyst matrixes 20 betweenthe ports 90, 92. The frame 52 of each of the substrate assemblies 50 isurged downwardly by the optional retaining devices 156, to help maintainthe substrate assemblies 50 in sealing engagement with the ports 90, 92.

The housing 80 both during heat up and steady state operation may beabout 100° C. cooler than the catalyst matrix 20. This is because thecatalyst matrix 20 may be subjected to exhaust gases (or another fluidto be treated that is at an elevated temperature), but has nowhere toconduct or radiate heat away. In contrast, the housing 80 may radiate orconduct heat into the surrounding environment. Upon shutdown or lowengine loads, the rate of the temperature loss from the housing 80 maybe less than that of the catalyst matrix 20, because the housing 80 maybe of heavy gauge metal whereas the catalyst matrix 20 may be formed ofthin sheet metal with large surface area. Thus, the housing 80 under lowengine load conditions may be about 100-150° C. hotter than the catalystmatrix 20.

Considering the overall size of a stationary or industrial sized unit,this temperature differential may result in significant dimensionaldifferences between the housing 80 and the catalyst matrix 20. Thesemust be accommodated to avoid undue stress damaging either componentwhile ensuring adequate sealing therebetween so as to avoid fluidescaping between the housing 80 and the catalyst matrix 20. Some largeindustrial catalytic converters are sealed about a periphery of thecatalyst substrate with a ceramic fiber material. Such material may beprone to erosion, for example, by high velocity gas and mechanicalbreakdown through compression and vibration. Furthermore such materialis easily torn and difficult to maintain in place during installation,particularly with larger units. By avoiding a use of a gasket, the sealformed between the flange element 40, and the interior sealing surfaces110, 168 may provide good durability throughout wide range of operatingtemperatures, and the maintenance and durability issues associated withconventional gaskets may be eliminated.

While the above description provides examples of one or more apparatusesor methods, it will be appreciated that other apparatuses or methods maybe within the scope of the accompanying claims.

We claim:
 1. A catalytic converter apparatus, comprising: a housingcomprising an inlet port, an outlet port spaced apart from the inletport, a chamber between the inlet and outlet ports, an access openingfor access to the chamber, and an interior sealing surface generallyencompassing a periphery of one of the inlet and outlet ports in thechamber; a substrate assembly insertable into the chamber and removablefrom the chamber through the access opening, the substrate assemblycomprising a catalyst matrix for treating fluid; and a positioningmechanism for removably supporting the substrate assembly within thechamber so that movement of the substrate assembly in a lateraldirection generally parallel to the interior sealing surface moves thesubstrate assembly in an axial direction generally perpendicular to theinterior sealing surface, wherein the substrate assembly comprises aframe for holding the catalyst matrix, wherein the positioning mechanismguides the frame to move the substrate assembly in the axial directioninto sealing engagement with the one of the inlet and outlet ports,thereby providing a fluid flow path through the catalyst matrix betweenthe inlet and outlet ports, wherein force applied to the frame in thelateral direction resolves into force of the substrate assembly in theaxial direction bearing against the interior sealing surface, whereinthe positioning mechanism comprises first and second guiding surfacesfor slidingly receiving the frame, the first and second guiding surfacesarranged on generally opposing first and second sides of the chamber,respectively, and wherein the guiding surfaces are inclined at an anglerelative to the interior sealing surface.
 2. The apparatus of claim 1,wherein the substrate assembly comprises a flange element extendingabout a periphery of an end face of the catalyst matrix, the flangeelement abutting the interior sealing surface, and the flange elementand the interior sealing surface engage to seal the fluid flow pathbetween the catalyst matrix and the one of the inlet and outlet portswithout a gasket.
 3. The apparatus of claim 2, wherein the interiorsealing surface is formed by an inner wall element that is fixed to anend wall generally surrounding the one of the inlet and outlet ports. 4.The apparatus of claim 3, wherein the flange element is configured toflex against the inner wall element.
 5. The apparatus of claim 4,wherein the flange element is coupled to an annular wall generallysurrounding a peripheral mantle of the catalyst matrix, and the flangeelement is flared outwardly at an angle relative to the annular wall. 6.The apparatus of claim 5, wherein the substrate assembly comprises aline of reduced thickness arranged generally between the annular walland the flange element.
 7. The apparatus of claim 1, wherein thesubstrate assembly comprises a flange element extending about aperiphery of an end face of the catalyst matrix, and the flange elementand the interior sealing surface engage to seal the fluid flow pathbetween the catalyst matrix and the one of the inlet and outlet portswithout a gasket.
 8. The apparatus of claim 7, wherein the framecomprises a front plate having an opening, and the catalyst matrix isreceived in the opening with the flange element engaging the front platein opposed relation, so that the frame distributes force from thepositioning mechanism to the flange element.
 9. The apparatus of claim1, wherein the frame comprises first and second flaps that slidinglymate with the first and second guiding surfaces, respectively, the firstand second flaps extending outwardly relative to the catalyst matrix.10. The apparatus of claim 9, wherein the positioning mechanismcomprises a retaining device for maintaining the substrate assembly insealing engagement with the one of the inlet and outlet ports.
 11. Theapparatus of claim 10, wherein the retaining device exerts a force ontothe frame generally in the lateral direction.
 12. The apparatus of claim9, wherein the flaps and the guiding surfaces are configured tofrictionally engage so that the substrate assembly locks into positionrelative to the housing.
 13. The apparatus of claim 12, wherein thepositioning mechanism comprises a retaining device for maintaining thesubstrate assembly in sealing engagement with the one of the inlet andoutlet ports.
 14. The apparatus of claim 13, wherein the retainingdevice exerts a force onto the frame generally in the lateral direction.15. The apparatus of claim 1, wherein the positioning mechanismcomprises a retaining device for maintaining the substrate assembly insealing engagement with the one of the inlet and outlet ports.
 16. Theapparatus of claim 15, wherein the retaining device exerts a force ontothe frame generally in the lateral direction.
 17. The apparatus of claim1, wherein the housing comprises first and second ones of thepositioning mechanisms within the chamber, the first and secondpositioning mechanisms arranged to guide first and second ones of thesubstrate assemblies into sealing engagement with the inlet and theoutlet ports, respectively, movement of the first and second substrateassemblies in the lateral direction causes the substrate assemblies tomove outwardly away from one another in the axial direction, and each ofthe positioning mechanisms comprises a retaining device for exerting aforce onto the respective substrate assembly generally in the lateraldirection to maintain the substrate assembly in sealing engagement. 18.A catalytic converter apparatus, comprising: a housing comprising aport, and an interior sealing surface generally encompassing a peripheryof the port; a positioning mechanism comprising first and second guidingsurfaces arranged on generally opposing first and second sides withinthe housing, respectively; and a substrate assembly removably supportedby the positioning mechanism within the housing, the substrate assemblycomprising a frame that is slidingly received by the first and secondguiding surfaces, a catalyst matrix supported by the frame andcomprising an end face, and a flange element extending about a peripheryof the end face of the catalyst matrix, wherein the flange element abutsthe interior sealing surface, wherein the frame engages the flangeelement, wherein each of the first and second guiding surfaces isinclined at an angle relative to the interior sealing surface so that afirst force applied to the substrate assembly in a lateral directionresolves into a second force of the substrate assembly in an axialdirection, and wherein the frame distributes the second force to theflange element so that the flange element bears against the interiorsealing surface to provide a generally sealed fluid flow path throughthe catalyst matrix and the port.
 19. A catalytic converter apparatus,comprising: a housing comprising an inlet port, an outlet port spacedapart from the inlet port, a chamber between the inlet and outlet ports,an access opening for access to the chamber, and an interior sealingsurface generally encompassing a periphery of one of the inlet andoutlet ports in the chamber; a substrate assembly insertable into thechamber and removable from the chamber through the access opening, thesubstrate assembly comprising a catalyst matrix for treating fluid, anda frame for holding the catalyst matrix, the frame comprising first andsecond flaps extending outwardly relative to the catalyst matrix; and apositioning mechanism for removably supporting the substrate assemblywithin the chamber, the positioning mechanism comprising first andsecond guiding surfaces arranged on generally opposing first and secondsides of the chamber, respectively, wherein the first and second flapsof the frame slidingly mate with the first and second guiding surfaces,respectively, of the positioning mechanism, and wherein each of thefirst and second guiding surfaces is inclined at an angle relative tothe interior sealing surface so that movement of the substrate assemblyin a lateral direction generally parallel to the interior sealingsurface moves the substrate assembly in an axial direction generallyperpendicular to the interior sealing surface.